Enrichment processes of arsenic in oxidic sedimentary rocks – from geochemical and genetic characterization to potential mobility.
Loading...
Files
Accepted version
Date
2010-06-01
Authors
Banning, Andre
Rüde, Thomas R.
Journal Title
Journal ISSN
Volume Title
Publisher
Elsevier
Published Version
Abstract
Sedimentary marine iron ores of Jurassic age and Tertiary marine sandy sediments containing iron hydroxides concretions have been sampled from boreholes and outcrops in two study areas in Germany to examine iron and arsenic accumulation processes. Samples were analyzed for bulk rock geochemistry (INAA/ICP-OES), quantitative mineralogy (XRD with Rietveld analysis), element distribution (electron microprobe) and arsenic fractionation (sequential extraction). Bulk Jurassic ores contain an average arsenic content of 123 μg g−1 hosted in mainly goethite ooids which slowly formed in times of condensed sedimentation. Enrichment occurred syndepositionally and is therefore characterized as primary. Iron concretions in Tertiary sediments mainly consist of goethite and yield arsenic up to 1860 μg g−1. The accumulation process is secondary as it took place in the course of oxidation of the originally reduced marine sediments under terrestrial conditions, leading to element redistribution and local enrichment in the near-surface part. The scale of enrichment was assessed calculating Enrichment Factors, indicating that arsenic accumulation was favoured over other potential contaminants. In spite of higher bulk arsenic contents in the oxidic rocks, the mainly pyrite-hosted As pool within the reduced deeper part of the Tertiary sediments is shown to have a higher potential for remobilization and creation of elevated arsenic concentrations in groundwater.
Description
Keywords
Arsenic , Accumulation process , Iron mineral , Enrichment factor , Redox conditions , Mobilization
Citation
Banning, A. and Rüde, T. R. (2010) 'Enrichment processes of arsenic in oxidic sedimentary rocks - from geochemical and genetic characterization to potential mobility', Water Research, 44 (19), pp. 5512-5531. doi: 10.1016/j.watres.2010.05.034